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Design of Linear RF Outphasing Power Amplifiers

Design of Linear RF Outphasing Power Amplifiers

Copyright: 2003
Pages: 218
ISBN: 9781580533744

Hardback $108.00 Qty:
Digital download and online $102.00 Qty:
This is the first book devoted exclusively to the outphasing power amplifier, covering the most recent research results on important aspects in practical design and applications. A compilation of all the proposed outphasing approaches, this is an important resource for engineers designing base station and mobile handset amplifiers, engineering managers and program managers supervising power amplifier designs, and R&D personnel in industry. The work enables you to: design microwave power amplifiers with higher efficiency and improved linearity at a lower cost; understand linearity and performance tradeoffs in microwave power amplifiers; and understand the effect of new modulation techniques on microwave power amplifiers. The book opens with an introduction to wireless communication standards and the requirements they impose on power amplifiers, together with a historical review of the outphasing power amplifier. Plus, this unique resource investigates various factors that contribute to outphasing system linearity degradation, reviews and compares various approaches for path mismatch reduction and linearity performance improvement. What's more, the book raises the issue of efficiency-isolation trade-off on power combining, discusses combining methods and choices of power amplifiers, and analyzes efficiency enhancement techniques.
Introduction - the Role of Power Amplifiers in Wireless Communication Systems. Characterization of Power Amplifier for Wireless Communications. Power Amplifier Linearization and Efficiency Enhancement Techniques. Outphasing Microwave Power Amplifiers. References.; Linearity Performance of Outphasing Power Amplifier Systems -Introduction. Digital Modulation Techniques. Baseband Filtering of Digital Data. Signal Component Separation for Outphasing Amplifiers. Path Imbalance and Its Effects on Linearity. Effect of Quadrature Modulator Errors on Linearity. SCS Quantization Error Effects on Outphasing Systems. Linearity Effects of Reconstruction Filter and DSP Sampling Rate. Summary. References.; Path Mismatch Reduction Techniques for Outphasing Amplifiers -Introduction. Correction Schemes Based on Training Vectors. Correction Schemes Transparent to Data Transmission. Correction Schemes for Multicarrier and Broadband Applications. VCO-Derived Synthesis. Summary. Appendix. References. ; Power Efficiency Enhancement Techniques -Introduction. Power Combiners. Choice of Amplifier. Design for Class A, B and C Amplifiers. Chireix Power Combining. Design for Switching-Mode Amplifiers. Application of Lossy Power Combiners. Probability Distribution of Output Power. Power Recycling in Outphasing Amplifiers. Summary. Appendix. References.; Conclusions - Research Summary. Future Research Directions.;
  • Peter M. Asbeck Peter M. Asbeck is a professor of Department of Electrical and Computer Engineering at the University of California, San Diego and has done extensive work at Philips Laboratories and the Rockwell International Science Center as principal scientist, technical staff member, researcher and teacher. He holds a Ph.D., M.S. and B.S. in electrical engineering from the Massachusetts Institute of Technology and is a Fellow of the IEEE.
  • Lawrence E. Larson Lawrence E. Larson is director of the Center for Wireless Communications at the University of California, San Diego and past CWC Industry Chair Professor in Wireless Communications, Department of Electrical and Computer Engineering. A Fellow of the IEEE, he has conducted numerous research and development projects at Hughes Research Laboratories and Hughes Network Systems. He holds an M.B.A. and a Ph.D. in electrical engineering from the University of California, Los Angeles, and a M. Eng. and B.S. in electrical engineering from Cornell University, New York.
  • Xuejun Zhang Xuejun Zhang is senior engineer at Qualcomm Inc. He holds a Ph.D. in electrical engineering from the University of California, San Diego, an M.S. in electro-optics from the National University of Singapore, and a B.S. in semiconductor physics from Peking University, China. He has published extensively.
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